Data stream converter

ABSTRACT

A method and system for converting XML files to and from files in a data format based on hierarchies in real-time. A method for converting from XML to the data format based on hierarchies includes: applying a stylesheet to at least one XML file thereby generating at least one data record in an intermediate format and including information included in the at least one XML file; and, translating the at least one record in the intermediate format to the data format based on hierarchies. A method for converting from a data format based on hierarchies to XML includes: translating at least one record including information stored in the file format based on hierarchies to an intermediate format; and, applying a stylesheet to the at least one record in the intermediate format thereby generating at least one XML file being indicative of the information and suitable for transmission.

RELATED APPLICATIONS

This application is a continuation application of co-pending U.S. patent application Ser. No. 14/756,118 entitled System and Method for Efficient Data Handling Across Multiple Systems, filed Aug. 3, 2015, which is a continuation application of U.S. patent application Ser. No. 13/999,007 entitled System and Method for Converting Data Relating To An Insurance Transaction, filed Dec. 31, 2013, now U.S. Pat. No. 9,098,504, which is a continuation application of U.S. patent application Ser. No. 13/694,939 entitled Real-Time Single Entry Multiple Carrier Interface (SEMCI), filed Jan. 22, 2013, now U.S. Pat. No. 8,682,915, which is a continuation application of U.S. patent application Ser. No. 12/932,564 entitled Real-Time Single Entry Multiple Carrier Interface (SEMCI), filed Feb. 28, 2011, now U.S. Pat. No. 8,359,321, which is a continuation application of U.S. patent application Ser. No. 12/657,772 entitled Real-Time Single Entry Multiple Carrier Interface (SEMCI), filed Jan. 27, 2010, now U.S. Pat. No. 7,900,138, which is a continuation application of U.S. patent application Ser. No. 09/952,990, now U.S. Pat. No. 7,657,833 entitled Real-Time Single Entry Multiple Carrier Interface (SEMCI), filed Sep. 14, 2001, which application claims the benefit of U.S. Provisional Patent Application Ser. No. 60/232,711 filed on Sep. 15, 2000, the entire contents of all of which applications are hereby incorporated by reference herein for all purposes.

FIELD OF INVENTION

This invention relates generally to the implementation of several standards developed by ACORD, an insurance industry standards organization; and particularly to a Web Transaction Interface, XML Insurance and Surety Service Specification, and the EDI standard AL3.

Computer Program Listing Appendix

A Computer Program Listing Appendix, containing four (4) total files on a single compact disc, two (2) copies of which are submitted, is included with this application and incorporated by reference herein. The first file, named “listing1 (00135294xBC424).TXT”, is 8,192 bytes and was created on Aug. 3, 2015. The second file, named “listing2 (00135293xBC424).TXT”, is 28,672 bytes and was created on Aug. 3, 2015. The third file, named “listing3 (00135292xBC424).TXT”, is 16,384 bytes and was created on Aug. 3, 2015. The fourth file, named “listing4 (00135295xBC424).TXT”, is 14,336 bytes and was created on Aug. 3, 2015.

BACKGROUND OF THE INVENTION

The present Single Entry Multiple Carrier Interface (SEMCI) evolved out of the need for independent insurance agents to submit information to multiple insurance carriers. Historically, agents were required to use forms and systems provided by each carrier. Information common to all carriers was re-entered for each carrier creating redundant work for agents. To reduce this redundant work, ACORD defined the EDI standard known as AL3 and SEMCI was adopted as an insurance industry approach.

AL3 is focused on the communication between insurance carriers, their agents and other trading partners and has been in use since the 1980's. This EDI standard is a common set of rules that allow separate computer systems to talk to each other, to communicate policy data, accounting data, claims data, and application data for personal and commercial insurance, surety and specialty lines. SEMCI was implemented as a batch-oriented, store-and-forward “Electronic Data Interchange” (EDI) model using a private computer network. Agents and carriers submit EDI transactions over a private computer network to a clearinghouse. The clearinghouse places transactions in the “mail box” of the appropriate party and delivers the contents of each party's “mail box” to them on request.

With the advent of the Internet and related Internet standards, secure business-to-business commerce over a public network is now a reality. The insurance industry seeks to exploit this capability and Real-Time SEMCI is an implementation of electronic business-to-business commerce for insurance. Real-Time SEMCI provides agents the ability to enter data once into their agency management system and transmit that data over the Internet to multiple insurance company systems. The receiving insurance carriers process the transactions and return replies to the agent. For example, agents can request and receive quotes or submit applications for insurance. The implementation of Real-Time SEMCI relies on ACORD's Web Transaction Interface standard and ACORD's XML Insurance And Surety Service Specification. The Web Transaction Interface standard prescribes the communication protocol for this business as HTTP and it specifies an HTML form tag name that will contain transactions. ACORD's XML Insurance And Surety Service Specification defines business transactions using the World Wide Web Consortium's (W3C) XML standard.

As is well understood by those possessing an ordinary level of skill in the pertinent art, Hypertext Transfer Protocol, or HTTP, is a request/response application-level protocol for distributed, collaborative, hypermedia information systems. HTML is an authoring language used to create documents accessible via the World Wide Web (WWW) or (Web). HTML defines a structure and layout of a Web document by using a variety of tags and attributes. XML is a specification developed by the W3C especially for Web documents. XML allows designers to create their own customized tags, enabling the definition, transmission, validation and interpretation of data between applications and between organizations. Extensible Stylesheet Language (XSL) is a language for expressing stylesheets. It consists of a language for transforming XML documents, and an XML vocabulary for specifying formatting semantics. An XSL stylesheet specifies the presentation of a class of XML documents by describing how an instance of the class is transformed into an XML document that uses the formatting vocabulary.

It is an object of the present invention to translate from ACORD's XML Insurance And Surety Service Specification format to ACORD's AL3 EDI file format, so that insurance information communicated over the Internet or by other means and can be processed in the ACORD AL3 EDI file format.

It is a further object of the present invention to translate from ACORD's AL3 EDI file format to ACORD's XML Insurance And Surety Service Specification format so that insurance information processed in the AL3 format can be communicated over the Internet or by other means in ACORD's XML Insurance And Surety Service Specification format.

It is a further object of the invention to reduce the time and the cost required to rate and quote insurance policies.

SUMMARY OF THE INVENTION

A method and system for converting ACORD XML files to and from ACORD AL3 files in real-time. The method for converting from ACORD XML to ACORD AL3 format includes: applying a stylesheet to at least one ACORD XML file thereby generating at least one data record in an intermediate format and including information included in the at least one ACORD XML file; and, translating the at least one record in the intermediate format to ACORD AL3 format. The method for converting from ACORD AL3 files to ACORD XML files includes: translating at least one record including information stored in the ACORD AL3 file format to an intermediate format; and, applying a stylesheet to the at least one record in the intermediate format thereby generating at least one ACORD XML file being indicative of the information and suitable for transmission.

BRIEF DESCRIPTION OF THE DRAWINGS

Various other objects, features and advantages of the invention will become more apparent by reading the following detailed description in conjunction with the drawings, which are shown by way of example only, wherein:

FIG. 1 illustrates a system topology overview utilized according to a preferred form of the present invention;

FIGS. 2a and 2b illustrate a data hierarchy for the AL3 file format;

FIG. 3 illustrates an overview of XML file format to AL3 format translation and an AL3 file format to XML format translation according to a preferred form of the present invention.

DETAILED DESCRIPTION

The present invention, referred to as “Real-Time SEMCI”, uses two emerging ACORD standards: the Web Transaction Interface (WTI) and the XML Insurance and Surety Service Specification. The WTI enables companies to conduct transactions with agents over the Web instead of via relatively expensive private networks. The XML Insurance and Surety Service Specification defines a set of industry-standard business transactions.

In the explanation that follows, it is assumed that AL3 files originate with a carrier's system and XML files originate with a carrier's trading partner. The present invention operates to translate one into the other and vice versa.

Referring now to the Figures, like references identify like elements of the invention. As set forth, AL3 is an insurance industry standard file format, a sample of which appears in text form in the Computer Program Listing Appendix, part of which is reproduced as LISTING 1 as follows:

LISTING 1 1MHG161  IBM203HIGT02   IBM203APPLIE   98695048 2TRG201   60   3P CPKG  FMGBN B    THE HARTFORD 0001990924   9909013NBQ 2TCG135  900409205052031503309331092210937205043251010 5BIS172 1 B10001    CPat's Place ??????????????????????????????RTBOP- 1     IN 9BIS168  B10001 ??????????????????????????????????????????????????????????????????????? ??????????????? ????????????????????????????????????? 5BPI240 3 F100015BISB10001  98SBAAC3043  ??????????19682 BOP ????9909010009011???????????????????00001254093+00001254093+??PAAG?E???????????? ???? ??????00001254093+??????????????????????????????????????????????????????????????? ????AAG 5PAY101 2 F200015BPIF10001 FL???????????????????????????????????????????????USFL 6CP0173 5 F200015BPIF10001 CTN?????????????????????????????????????????????????????????????????????????????????? ????????????????????? 59430000???RLSCP ?????????????????????????????????? 5DSF058  F200015BPIF10001   01FRCOL?????F000100000?????? 5DCV113 1 F200015BPIF10001  FRCOL 5LAG199 1 F200015BPIF10001   000175 Main St ??????????????????????????????Hartford    CT06115 ??????????????????????????????????????????????????????? 5LAG199 1 F200025BPIF10001  0002250 Second St ??????????????????????????????Tampa     FL32004 ???????????????????9999 ??????????????? ?????????????? 5PIG152 1 G100015BPIF10001  BOPGL????00000000493+???19682 990901???????????????????????????????????????????????????????????? 5DCV113 1 G200025PIGG10001  EAOCC01000000 5DCV113 1 G200035PIGG10001  GENAG02000000 5DCV113 1 G200045PIGG10001  PRDC002000000 5DCV113 1 G200055PIGG10001  PIADV01000000 5DCV113 1 G200065PIGG10001  MEDEX00010000 5DCV113 1 G200075PIGG10001  FIRDM00300000 5LAG199 1 L100035PIGG10001 0001??????????????????????????????????????????????????????????????????????????????? ????????????????????????????????????????????????????????????????? 5SLC137  N100015LAGL10003  0175 Main St       Hartford     CT 06115      ?????

Note that to improve readability of the hierarchy, line breaks have been added between data groups to visually set them off from each other and that the data group names and processing levels have been highlighted. Of course, highlighting and line breaks do not exist in the normal AL3 file format. The three digits that follow the data group name determine the actual length of each data group (e.g. 1MHG data group is 161 characters long, 2TRG is 201, for example). Any reference to any LISTING throughout the specification herein signifies that the same result or effect occurs as when applied to the entire corresponding listing as appears in the Computer Program Listing Appendix. Listing 1 illustrates a text form of an AL3 file format. Listing 2 illustrates the data of the AL3 file format of Listing 1 organized according to a preferred form of the invention. Listing 3 illustrates a style sheet utilized according to a preferred form of the invention; and Listing 4 illustrates the data of Listing 1 in an XML file format organized according to a preferred form of the invention.

Referring still to LISTING 1, the formats are determined in advance based upon what kind of data the file will contain. Representative information contains data regarding by way of example, billing, new policy generation and inquiries regarding cancellation. The data format follows a hierarchy as indicated in FIGS. 2a and 2b , with a more detailed illustration of a hierarchy for a Business Owners Policy being provided in FIG. 2b . As is well understood by those possessing an ordinary skill in the pertinent art, the ACORD AL3 format is based on data elements, data groups and hierarchies. An ACORD data element is the smallest piece of data collected and stored. Data Groups are logical collections of data elements. Hierarchies are used to establish a logical relationship of data groups to one another. In the hierarchy labeled 220 in FIG. 2a , each level is associated with the level immediately preceding it. For example, a Location group 224 is associated with a Policy group 223, a Risk group 225 is associated with a Location group and so on (e.g. coverage group 226). If needed, “Dummy” Groups are created to preserve the hierarchy.

For sake of explanation the following discussion will follow a transaction which originates in a mainframe or other processing system such as that illustrated in FIG. 1. The text of LISTING 1 is a typical ACORD standard representation; in this instance for illustration an AL3 file delimited by the 1MHG and 3MTG data groups 200, 230 as shown in FIG. 2 a. Between delimiter data groups 200 and 230, the transaction sequence begins with data group 210, and transaction hierarchy 220, and proceeds with the next transaction data group 210′ and next transaction hierarchy 220′. The AL3 file of LISTING 1 contains one transaction that begins with the 2TRG and 2TCG data groups 210 as shown in FIG. 2 a. Still referring to LISTING 1, the text thereof indicates that ACORD data group 5BIS (shown as 222 in FIG. 2a ) follows. This data identifies the basic insured information related to this specific policy and other data as is well understood by those possessing ordinary skill in the pertinent art.

Referring now also to FIG. 1, the first step is to retrieve an AL3 file, such as that illustrated in LISTING 1 and discussed hereto, from the mainframe or other processing system computer 106 via a message server 105. The next step is to translate the AL3 file retrieved data and organize it utilizing programming techniques well known by those skilled in the art of programming to translate and organize data, referred to herein as a Faux File Generator application running on the application server 103, such as is illustrated in the Computer Program Listing Appendix part of which is reproduced as LISTING 2 as follows:

LISTING 2 <?xml version= “1.0” standalone= “no”?> <!DOCTYPE AL3 (View Source for full doctype...)> =<AL3> =<Group Name= “1MHG ”Length= “161” LineOfBusiness= “Common”> <Sequence Index =“ 0” Length = “10” > 1MHG161 </Sequence> <Sequence Index = “1” Length = “18”> 1BM203HIGT02 </Sequence> <Sequence Index = “2” Length = “18”> 1BM203APPLIE </Sequence> <Sequence Index = “3” Length = “10”> 98695048 </Sequence> <Sequence Index = “4” Length = “12” /> <Sequence Index = “5” Length = “6” /> <Sequence Index = “6” Length = “4”/> <Sequence Index = “7” Length = “6” /> <Sequence Index = “8” Length = “13” /> <Sequence Index = “9” Length = “1” /> <Sequence Index = “10” Length = “10” /> <Sequence Index = “11” Length = “2” /> <Sequence Index = “12” Length = “1” /> <Sequence Index = “13” Length = “4” /> <Sequence Index = “14” Length = “6” /> <Sequence Index = “15” Length = “20” /> <Sequence Index = “16” Length = “20” /> </Group> <Group Name = “2TRG” Length= “201” LineOfBusiness=“Common”> <Sequence Index = “0” Length = “10”>2TRG201</Sequence> <Sequence Index = “1” Length = “2”> 60 </Sequence> <Sequence Index = “2” Length = “8”/> <Sequence Index = “3” Length = “1”/> <Sequence Index = “4” Length = “1”>3</Sequence> <Sequence Index = “5” Length = “2”>P<Sequence> <Sequence Index = “6” Length = “1”>C<Sequence> <Sequence Index = “7” Length = “5”>PKG<Sequence> <Sequence Index = “8” Length = “3”>FMG<Sequence> <Sequence Index = “9” Length = “1”>B<Sequence> <Sequence Index = “10” Length = “1”>N<Sequence> <Sequence Index = “11” Length = “1”/> <Sequence Index = “12” Length = “1”>B<Sequence> <Sequence Index = “13” Length = “10”/> <Sequence Index = “14” Length = “25”> THE HARTFORD </Sequence> <Sequence Index = “15” Length = “10”/>

The Faux File generator application organizes or retranslates the ACORD file LISTING 1 into an intermediary file format such as that illustrated in the Computer Program Listing Appendix part of which is reproduced as LISTING 2 above (referred to as Faux file 3 herein for sake of explanation) that can be read by a function that converts it to XML format.

LISTING 3 <?xml version=“ 1.0”?>    =<!- -    XSL style sheet to transform a BOP quote response from a “faux” AL3 stream to XML.    Copyright (c) The Hartford    All rights reserved.  -- > =<xsl:stylesheet version= “1.0” xmlns:xsl= “http://www.w3.org/1999/XSL/Transform”>   =<xsl:template match=”/”>    =<BOPPolicyQuoteInqRs>      <RqUID/>    =<Status>      =<xsl:choose>       =<xsl:when test=“//Group[@Name=‘2TRG’]/Sequence[@index=‘4’] = ‘3’”>       <StatusCode>1<</StatusCode>       <Severity>Info</Severity>    =</xsl:when>      =<xsl:otherwise>       <StatusCode>100</StatusCode>       <Severity>Error</Severity>         <StatusDesc>General Error<StatusDesc>      =<xsl:otherwise>    =<xsl:choose>   =<Status> =<xsl:choose>   =<xsl: when test=“//Group [@Name=‘2TRG’]/Sequence[@Index=‘4’] =‘3’”>    =<Producer>      =<ContractNumber>         <xsl:value-of          select=“//Group[@Name=‘1MHG’]/Sequence[@Index=‘3’]” />      </ContractNumber>      =<ProducerSubCode>       <xsl:value-of         select=“//Group[@Name=‘5BIS’]/Group[@Name=‘5BPI’]/Sequence          [@Index=‘8’] ”/>      </ProducerSubCode>    </Producer>   =<Customer>    = <CustomerName>

LISTING 2 illustrates the organization or ordering, e.g. parsing, of the AL3 file into a new kind of list which is referred to as a FAUX File 3, as exemplified by LISTING 3 noting the references to 1MHG, 2TRG, 2TCG, and 5BIS. The data of the Faux file 3 as exemplified by LISTING 2 is then translated into an ACORD XML for Insurance And Surety Service or other suitable tagged language as is shown in Computer Program Listing Appendix, part of which is reproduced as LISTING 4 below. Preferably, the process looks at each AL3 transaction, which begins with a 2TRG header.

LISTING 4 <?xml version = “1.0” encoding =”UTF-8”?>   = <BOPPolicy QuoteInqRs>    <RqUID/>   = <Status>    <Status Code> 1 </Status Code>    <Severity>Info<Severity>    </Status>   =<Producer>    <ContractNumber>98695048</ContractNumber>    <ProducerSubCode>?????????<ProducerSubCode>   </Producer> =<Customer>   =<CustomerName>    <NameType>CORP</NameType>   = <CommercialName>      <Company Name/>    </CommercialName>    <CustomerName>Pat's Place</Customer Name> = <CustomerAddress>    <Addr1>???????????????????????????????????????????????</Addr1>    <Addr2>???????????????????????????????????????????????</Addr2>    <City>??????????????????</City>    <StateProv>??</StateProv>    <PostalCode>?????????/PostalCode>   </CustomerAddress> = <CustomerNumber>    <ItemIDType>AgcyID</ItemIdType>    <ItemId>RTBOP-1</ItemId>   </CustomerNumber>   </Customer> = <CommercialPolicy>    <PolicyNumber>98SBAAC3043</PolicyNumber>    <LOBCode>BOP</LOBCode>    <NAICCode>19682</NAICCode>    = <EffectiveDate>      <Year />      <Month />      <Day />    </EffectiveDate>

FIGS. 2a and 2b show the hierarchical representation of the data in LISTING 1.

An XML stylesheet such as that illustrated in LISTING 3 above is preferably used to translate the Faux File as exemplified by LISTING 2 to the XML file as exemplified by LISTING 4 so that it contains the correct XML file format and accompanying data. There are preferably as many style sheets as there are “kinds of transactions” to translate.

The XML file as exemplified by LISTING 4 is then passed to Web Server 102 (see FIG. 1) and is transmitted over the Internet 107 and received remotely, presumably by an agency system 101 of an agent of the insurance company utilizing conventional methodology.

The process is transitive or bi-directional in that an XML format file generated at an agency system 101 will be decoded or translated using a style sheet into a Faux file and then translated into the AL3 file format before being sent to the mainframe or other processing system computer 106.

Referring now also to FIG. 3, at the start of the process 310, XML request transactions are received from computer 101 (e.g. agency system, application service provider, insurance portal) of FIG. 1 and converted 320 to pseudo AL3 request transactions, or faux files, by applying a stylesheet, such as an XSL stylesheet. The data from the created faux file is then translated 330 into AL3 (including removing XML tags) and delivered 340 to the mainframe 106 or other processing system 106. AL3 response transactions are generated by the processing system and are returned to the translation process 350. AL3 response files are converted 360 into pseudo AL3 response transactions, or faux files (including adding XML tags). The data from the faux file is then translated 370 into XML formatted files using a style sheet. The XML file can then be transmitted 380 to suitable processor devices using the Internet and the process exited.

For sake of completeness, and referring again to FIG. 3 and a preferred embodiment of a system for implementing the present invention shown in FIG. 1, mainframe 106 or other processing systems 106 are electronically communicable with message servers 105. The message servers 105 are conventionally communicable with application servers 103. Application servers 103 perform the translating of AL3 files to the faux file 3 format and apply the stylesheets LISTING 4 to code the faux files 3 in XML format. The application servers 103 are conventionally communicable with web servers 102, which are conventionally communicable with agency computers 101, via a suitable communications medium such as the global interconnection of computers and computer networks commonly referred to as the Internet. Directory servers 104 are also preferably utilized and are communicable with application servers 103.

Although the invention has been described and pictured in a preferred form with a certain degree of particularity, it is understood that the present disclosure of the preferred form, has been made only by way of example, and that numerous changes in the details of construction and combination and arrangement of parts may be made without departing from the spirit and scope of the invention as hereinafter claimed. It is intended that the patent shall cover by suitable expression in the appended claims, whatever features of patentable novelty exist in the invention disclosed. 

Ws claimed is:
 1. A computer-implemented method for converting a received data stream from XML (Extensible Markup Language) format to an electronic data interchange (EDI) format, the EDI format being based on hierarchies, the method being executed by one or more processors, comprising: by a first computer system, receiving a data stream in XML format, the data stream including a transaction type identifier; by the first computer system, accessing a first translation tool corresponding to the transaction type identifier, and, using the accessed first translation tool, translating the received data stream to an intermediate data format having a plurality of tags, the tags incorporating sequence data, including one or more tags incorporating group delimiters and one or more tags incorporating transaction group identifiers; by the first computer system, accessing a second translation tool corresponding to the transaction type identifier, and translating the data stream in the intermediate data format to the EDI format based on hierarchies, employing the sequence data to format the data in the EDI format based on hierarchies, the formatting of the data stream in the EDI format based on hierarchies including arranging of alphanumeric data elements independent of font, and designation of delimiter data groups and transaction data groups arranged between the delimiter data groups using the one or more of the group delimiters and transaction group identifiers; and by the first computer system, providing the data stream in the EDI format based on hierarchies for output to a computing device.
 2. The computer-implemented method of claim 1, wherein the first translation tool is a stylesheet.
 3. The computer-implemented method of claim 2, wherein the stylesheet is an XSL (Extensible Stylesheet Language) stylesheet.
 4. The computer-implemented method of claim 1, wherein the converting to the EDI format based on hierarchies further comprises employing sequence index and length data of the sequence data to format the data in the EDI format based on hierarchies.
 5. The computer-implemented method of claim 1, wherein at least one of the tags incorporating sequence data comprises length data.
 6. The computer-implemented method of claim 1, wherein the EDI format based on hierarchies is an AL3 format.
 7. The computer-implemented method of claim 1, wherein the translating to the EDI format based on hierarchies further comprises removing the tags.
 8. A computer interface system for converting a data stream from XML (Extensible Markup Language) format to an EDI (Electronic Data Interchange) format based on hierarchies, comprising: a first computer system connected to a computer network and configured for bi-directional communication of data over the computer network, the first computer system comprising one or more processors and configured to: receive a data stream including a transaction type identifier in XML format; access a first translation tool corresponding to the transaction type identifier, and, using the accessed first translation tool, translate the received data stream to an intermediate data format having a plurality of tags, the tags incorporating sequence data, including one or more tags incorporating group delimiters and one or more tags incorporating transaction group identifiers; translate, using a second translation tool, the data stream from the intermediate data format to the EDI format based on hierarchies, employing the sequence data to format the data in the EDI format based on hierarchies, the formatting of the data in the EDI format based on hierarchies including arrangement of alphanumeric data elements independent of font and designation of delimiter data groups and transaction data groups arranged between the delimiter data groups using the one or more of the group delimiters and transaction group identifiers; and provide the data in the EDI format for output to a further computing device.
 9. The computer interface system of claim 8, wherein the first translation tool specifies a presentation of a class of XML documents.
 10. The computer interface system of claim 9, wherein the first translation tool is a stylesheet.
 11. The computer interface system of claim 8, wherein the EDI format based on hierarchies further comprises data elements, data groups being logical groupings of the data elements and hierarchies establishing logical relationships among the data groups.
 12. The computer interface system of claim 8, wherein the translating to the EDI format based on hierarchies further comprises employing sequence index and length data of the sequence data to format the data in the EDI format based on hierarchies.
 13. A computer-implemented method for converting data formatted based on hierarchies to XML (Extensible Markup Language) format data, the method being executed by one or more processors, comprising: by a first computer system, receiving a data stream in an EDI (Electronic Data Interchange) format based on hierarchies, the data stream including a transaction type identifier, delimiter data groups and transaction data groups arranged between the delimiter data groups; by the first computer system, accessing a translation tool, and using the accessed translation tool to translate the data stream to an intermediate data format having tags incorporating transaction type identifier data, sequence data and delimiter data group data, wherein the sequence data of at least one of the tags incorporating sequence data comprises data group name and length data; by the first computer system, accessing a second translation tool, corresponding to the transaction type identifier, and, using the second translation tool, converting the received data in the intermediate data format having tags to XML format, employing the data group name and length data of the sequence data to format the data in XML format, the formatting of the data in XML format including tags and arrangements of alphanumeric data elements independent of font; and providing, by the first computer system, the XML formatted data as an output.
 14. The computer-implemented method of claim 13, wherein the second translation tool is a stylesheet.
 15. The computer-implemented method of claim 14, wherein the stylesheet is an XSL (Extensible Stylesheet Language) stylesheet.
 16. The computer-implemented method of claim 13, wherein the received data stream is in AL3 EDI format.
 17. The computer-implemented method of claim 13, further comprising receiving the XML format data output at a web server, and furnishing the XML format data by the web server in response to an XML request transaction.
 18. A computer system for converting a data stream in an EDI (Electronic Data Interchange) format based on hierarchies to XML (Extensible Markup Language) format data, comprising: a first computer system connected to a computer network and configured for bi-directional communication of data over the computer network, the first computer system comprising one or more processors and configured to: receive a data stream in EDI format including a transaction type identifier, delimiter data groups and transaction data groups arranged between the delimiter data groups; access a first translation tool, and, using the first translation tool, translate the received data stream to an intermediate data format having tags incorporating the transaction type identifier, sequence data and delimiter data group data, wherein the sequence data of at least one of the tags incorporating sequence data comprises data group name and length data; access a second translation tool corresponding to the transaction type identifier; translate, using the second translation tool, the received data in the intermediate data format having tags to XML format, using the data group name and length data of the sequence data to format the data in XML format; and provide the XML format data as an output to a device.
 19. The computer system of claim 18, wherein the second translation tool specifies a presentation of a class of XML documents.
 20. The computer system of claim 19, wherein the second translation tool is a stylesheet. 